Removing axioms

Contents

Idea

Second-order arithmetic is a theory dealing with natural numbers and, what makes it “second-order”, sets of natural numbers1. SOA, or Z2Z_2 as it is often denoted, is proof-theoretically weak in comparison with ZFC, but still strong enough to derive “almost all of undergraduate mathematics” (Friedman).

Definition

The language of SOA consists of two sorts, here denoted NN and PNP N, together with

A constant 00 of type NN,

An unary function symbol s:N→Ns \colon N \to N,

Binary function symbols +,⋅:N×N→N+, \cdot \colon N \times N \to N,

A binary relation symbol <\lt of type N×NN \times N.

A binary relation symbol ∈\in of type N×PNN \times P N.

The axioms of SOA may be divided into two parts: the first part comprises the “first-order axioms” that deal only with the sort NN, and defines which is known as Robinson arithmetic. The second part comprises induction and comprehension schemes that involve the symbol ∈\in.

“First-order” axioms

Omitting the sort PNP N and the symbol ∈\in from the language, the axioms in this section give Robinson arithmetic. The logic throughout is standard first-order (predicate) logic with equality.

For all the formulas in this section, it is tacitly understood that there are universal quantifiers at the heads of formulas, binding all variables which appear freely.

The instance in the full induction scheme where φ\varphi is the formula n∈Xn \in X is called simply the induction axiom. The induction axiom together with the comprehension scheme implies the full induction scheme.

Subsystems of SOA

The theory described above gives full second-order arithmetic. However, in reverse mathematics, one often studies subsystems of weaker proof-theoretic strength than SOA, by limiting in some way the comprehension scheme (often also beefing up the single induction axiom with more instances of the induction scheme, to offset the weakening). The main examples are given in Wikipedia; a standard reference is Simpson.

References

The logic that governs the language and theory of Z2Z_2 is ordinary (first-order) predicate logic. The “second-order” aspect is really in the models, where one interprets the symbol ∈\in as membership in a background set theory, i.e., terms of type PNP N are interpreted as subsets of the set that interprets the type NN, and an extensionality axiom is in force. A full model is where PNP N is interpreted as the full power set of NN. When one sees absoluteness assertions such as “there is only one (full) model of SOA up to isomorphism,” it should be clear that this is meant with regard to a given background set theory. Cf. the fact that while there is, up to isomorphism, at most one natural numbers objectℕ\mathbb{N} in a given topos, the set of global elements Γ(ℕ)\Gamma(\mathbb{N}) might contain “non-standard elements” as viewed against the background SetSet. ↩